Multispectral Mueller Polarimetric Imaging Detecting Residual Cancer and Cancer Regression After Neoadjuvant Treatment for Colorectal Carcinomas

Overview

Journal J Biomed Opt

Specialties Biomedical Engineering
Ophthalmology

Date 2013 Apr 25

PMID 23612875

Citations 43

Authors

Angelo Pierangelo

Sandeep Manhas

Abdelali Benali

Clement Fallet

Jean-Laurent Totobenazara

Maria-Rosaria Antonelli

Tatiana Novikova

Brice Gayet

Antonello De Martino

Pierre Validire

Affiliations

Soon will be listed here.

Abstract

This work is devoted to a first exploration of Mueller polarimetric imaging for the detection of residual cancer after neoadjuvant treatment for the rectum. Three samples of colorectal carcinomas treated by radiochemotherapy together with one untreated sample are analyzed ex vivo before fixation in formalin by using a multispectral Mueller polarimetric imaging system operated from 500 to 700 nm. The Mueller images, analyzed using the Lu-Chipmann decomposition, show negligible diattenuation and retardation. The nonirradiated rectum exhibits a variation of depolarization with cancer evolution stage. At all wavelengths on irradiated samples, the contrast between the footprint of the initial tumor and surrounding healthy tissue is found to be much smaller for complete tumor regression than when a residual tumor is present, even at volume fractions of the order of 5%. This high sensitivity is attributed to the modification of stromal collagen induced by the cancer. The depolarization contrast between treated cancer and healthy tissue is found to increase monotonously with the volume fraction of residual cancer in the red part of the spectrum. Polarimetric imaging is a promising technique for detecting short-time small residual cancers, which is valuable information for pathological diagnosis and patient management by clinicians.

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